Polyurethanes: science, technology, markets, and trends
Gespeichert in:
| 1. Verfasser: | |
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| Format: | Elektronisch E-Book |
| Sprache: | English |
| Veröffentlicht: |
Hoboken, NJ, USA
Wiley
2021
|
| Ausgabe: | Second edition |
| Schriftenreihe: | Wiley Series on polymer engineering and technology
|
| Online-Zugang: | TUM01 |
| Beschreibung: | Description based on publisher supplied metadata and other sources |
| Beschreibung: | 1 Online-Ressource Illustrationen, Diagramme |
| ISBN: | 9781119669470 9781119669463 |
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| 100 | 1 | |a Sonnenschein, Mark F. |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Polyurethanes |b science, technology, markets, and trends |c Mark F. Sonnenschein |
| 250 | |a Second edition | ||
| 264 | 1 | |a Hoboken, NJ, USA |b Wiley |c 2021 | |
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| 505 | 8 | |a Cover -- Title Page -- Copyright Page -- Contents -- PREFACE -- ACKNOWLEDGMENTS -- CHAPTER 1 INTRODUCTION -- REFERENCES -- CHAPTER 2 POLYURETHANE BUILDING BLOCKS -- 2.1 POLYOLS -- 2.1.1 Polyethers -- 2.1.2 Polyester Polyols -- 2.1.3 Other Polyols -- 2.1.4 Filled Polyols -- 2.1.5 Seed Oil-Derived Polyols -- 2.1.6 Prepolymers -- 2.2 ISOCYANATES -- 2.2.1 TDI -- 2.2.2 Diphenylmethane Diisocyanates (MDI) -- 2.2.3 Aliphatic Isocyanates -- 2.3 CHAIN EXTENDERS -- REFERENCES -- CHAPTER 3 INTRODUCTION TO POLYURETHANE CHEMISTRY -- 3.1 INTRODUCTION -- 3.2 MECHANISM AND CATALYSIS OF URETHANE FORMATION -- 3.3 REACTIONS OF ISOCYANATES WITH ACTIVE HYDROGEN COMPOUNDS -- 3.3.1 Urea Formation -- 3.3.2 Allophanate Formation -- 3.3.3 Formation of Biurets -- 3.3.4 Formation of Uretdione (Isocyanate Dimer) -- 3.3.5 Formation of Carbodiimide -- 3.3.6 Formation of Uretonimine -- 3.3.7 Formation of Amides -- REFERENCES -- CHAPTER 4 THEORETICAL CONCEPTS AND TECHNIQUES IN POLYURETHANE SCIENCE -- 4.1 FORMATION OF POLYURETHANE STRUCTURE -- 4.2 PROPERTIES OF POLYURETHANES -- 4.2.1 Models and Calculations for Polymer Modulus -- 4.2.2 Models for Elastomer Stress-Strain Properties -- 4.2.3 The Polyurethane Glass Transition Temperature -- REFERENCES -- CHAPTER 5 ANALYTICAL CHARACTERIZATION OF POLYURETHANES -- 5.1 ANALYSIS OF REAGENTS FOR MAKING POLYURETHANES -- 5.1.1 Analysis of Polyols -- 5.1.2 Analysis of Isocyanates -- 5.2 INSTRUMENTAL ANALYSIS OF POLYURETHANES -- 5.2.1 Microscopy -- 5.2.2 IR Spectrometry -- 5.2.3 X-Ray Analyses -- 5.3 MECHANICAL ANALYSIS -- 5.3.1 Tensile, Tear, and Elongation Testing -- 5.3.2 DMA -- 5.4 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY -- 5.5 FOAM SCREENING: FOAMAT -- REFERENCES -- CHAPTER 6 POLYURETHANE FLEXIBLE FOAMS: CHEMISTRY AND FABRICATION -- 6.1 MAKING POLYURETHANE FOAMS -- 6.1.1 Slabstock Foams -- 6.1.2 Molded Foams -- 6.2 FOAM PROCESSES. | |
| 505 | 8 | |a 6.2.1 Surfactancy and Catalysis -- 6.3 FLEXIBLE FOAM FORMULATION AND STRUCTURE-PROPERTY RELATIONSHIPS -- 6.3.1 Screening Tests -- 6.3.2 Foam Formulation and Structure-Property Relationships -- REFERENCES -- CHAPTER 7 POLYURETHANE FLEXIBLE FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 7.1 APPLICATIONS -- 7.1.1 Furniture -- 7.1.2 Mattresses and Bedding -- 7.1.3 Transportation -- 7.1.4 The Molded Foam Market -- 7.2 TRENDS IN MOLDED FOAM TECHNOLOGY AND MARKETS -- REFERENCES -- CHAPTER 8 POLYURETHANE RIGID FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 8.1 REGIONAL MARKET DYNAMICS -- 8.2 APPLICATIONS -- 8.2.1 Construction Foams -- 8.2.2 Rigid Construction Foam Market Segments -- 8.2.3 Appliance Foams -- 8.3 BLOWING AGENTS AND INSULATION FUNDAMENTALS -- 8.3.1 Blowing Agents -- 8.3.2 Blowing Agent Phase‐Out Schedule -- 8.4 INSULATION FUNDAMENTALS -- 8.5 TRENDS IN RIGID FOAMS TECHNOLOGY -- REFERENCES -- CHAPTER 9 POLYURETHANE ELASTOMERS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 9.1 REGIONAL MARKET DYNAMICS -- 9.2 APPLICATIONS -- 9.2.1 Footwear -- 9.2.2 Nonfootwear Elastomer Applications and Methods of Manufacture -- 9.3 TRENDS IN POLYURETHANE ELASTOMERS -- REFERENCES -- CHAPTER 10 POLYURETHANE ADHESIVES AND COATINGS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 10.1 ADHESIVES AND COATINGS INDUSTRIES: SIMILARITIES AND DIFFERENCES -- 10.2 ADHESIVES -- 10.2.1 Adhesive Formulations -- 10.3 TRENDS IN POLYURETHANE ADHESIVES -- 10.4 COATINGS -- 10.4.1 Polyurethane Coating Formulations -- 10.4.2 Trends in Polyurethane Coatings -- REFERENCES -- CHAPTER 11 SPECIAL TOPIC: MEDICAL USES OF POLYURETHANE -- 11.1 MARKETS AND PARTICIPANTS -- 11.2 TECHNOLOGY -- 11.2.1 Catheters -- 11.2.2 Wound Dressings -- 11.2.3 Bioabsorbable Polyurethanes -- 11.2.4 Hydrogels -- 11.2.5 Gloves and Condoms -- 11.3 FUTURE TRENDS -- REFERENCES. | |
| 505 | 8 | |a CHAPTER 12 SPECIAL TOPIC: NONISOCYANATE ROUTES TO POLYURETHANES -- 12.1 GOVERNMENTAL REGULATION OF ISOCYANATES -- 12.2 NONISOCYANATE ROUTES TO POLYURETHANES -- 12.2.1 Reactions of Polycyclic Carbonates with Polyamines -- 12.2.2 Direct Transformations of Amines to Urethanes -- 12.2.3 Reactions of Polycarbamates -- 12.2.4 Conversion of Hydroxamic Acids to Polyurethane -- 12.2.5 Conversion of Hydroxylamines to Polyurethanes -- REFERENCES -- CHAPTER 13 POLYURETHANE HYBRID POLYMERS -- 13.1 INTRODUCTION -- 13.2 POLYURETHANE-ACRYLATE HYBRIDS -- 13.3 URETHANE-EPOXY HYBRIDS -- 13.4 URETHANE-SILICONE HYBRIDS -- 13.4.1 Silicone-Modified Prepolymers -- 13.4.2 Urethane-Silicone Hybrids Produced Using Diblock Compatibilizers -- 13.4.3 Hybrids Employing Covalent and Hydrogen‐Bonded Cross-Links -- 13.4.4 Polyurethane Hybridization with Polyhedral Oligomeric Silsesquixanes -- 13.5 POLYURETHANE-POLYOLEFIN HYBRIDS -- 13.6 HYBRIDIZATION VIA TRANSURETHANIFICATION -- REFERENCES -- CHAPTER 14 RECYCLING OF POLYURETHANES -- 14.1 INTRODUCTION -- 14.2 GLYCOLYSIS, HYDROLYSIS, AMINOLYSIS, AND ACIDOLYSIS -- 14.3 PYROLYSIS -- 14.4 RECYCLE FOR FUEL VALUE -- 14.5 REGRINDING AND INCORPORATION -- REFERENCES -- Index -- EULA. | |
| 776 | 0 | 8 | |i Erscheint auch als |a Sonnenschein, Mark F. |t Polyurethanes |d Newark : John Wiley & Sons, Incorporated,c2021 |n Druck-Ausgabe, Hardcover |z 978-1-119-66941-8 |
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Datensatz im Suchindex
| _version_ | 1804182734968455168 |
|---|---|
| adam_txt | |
| any_adam_object | |
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| author | Sonnenschein, Mark F. |
| author_facet | Sonnenschein, Mark F. |
| author_role | aut |
| author_sort | Sonnenschein, Mark F. |
| author_variant | m f s mf mfs |
| building | Verbundindex |
| bvnumber | BV047442536 |
| classification_tum | CHE 737 |
| collection | ZDB-30-PQE |
| contents | Cover -- Title Page -- Copyright Page -- Contents -- PREFACE -- ACKNOWLEDGMENTS -- CHAPTER 1 INTRODUCTION -- REFERENCES -- CHAPTER 2 POLYURETHANE BUILDING BLOCKS -- 2.1 POLYOLS -- 2.1.1 Polyethers -- 2.1.2 Polyester Polyols -- 2.1.3 Other Polyols -- 2.1.4 Filled Polyols -- 2.1.5 Seed Oil-Derived Polyols -- 2.1.6 Prepolymers -- 2.2 ISOCYANATES -- 2.2.1 TDI -- 2.2.2 Diphenylmethane Diisocyanates (MDI) -- 2.2.3 Aliphatic Isocyanates -- 2.3 CHAIN EXTENDERS -- REFERENCES -- CHAPTER 3 INTRODUCTION TO POLYURETHANE CHEMISTRY -- 3.1 INTRODUCTION -- 3.2 MECHANISM AND CATALYSIS OF URETHANE FORMATION -- 3.3 REACTIONS OF ISOCYANATES WITH ACTIVE HYDROGEN COMPOUNDS -- 3.3.1 Urea Formation -- 3.3.2 Allophanate Formation -- 3.3.3 Formation of Biurets -- 3.3.4 Formation of Uretdione (Isocyanate Dimer) -- 3.3.5 Formation of Carbodiimide -- 3.3.6 Formation of Uretonimine -- 3.3.7 Formation of Amides -- REFERENCES -- CHAPTER 4 THEORETICAL CONCEPTS AND TECHNIQUES IN POLYURETHANE SCIENCE -- 4.1 FORMATION OF POLYURETHANE STRUCTURE -- 4.2 PROPERTIES OF POLYURETHANES -- 4.2.1 Models and Calculations for Polymer Modulus -- 4.2.2 Models for Elastomer Stress-Strain Properties -- 4.2.3 The Polyurethane Glass Transition Temperature -- REFERENCES -- CHAPTER 5 ANALYTICAL CHARACTERIZATION OF POLYURETHANES -- 5.1 ANALYSIS OF REAGENTS FOR MAKING POLYURETHANES -- 5.1.1 Analysis of Polyols -- 5.1.2 Analysis of Isocyanates -- 5.2 INSTRUMENTAL ANALYSIS OF POLYURETHANES -- 5.2.1 Microscopy -- 5.2.2 IR Spectrometry -- 5.2.3 X-Ray Analyses -- 5.3 MECHANICAL ANALYSIS -- 5.3.1 Tensile, Tear, and Elongation Testing -- 5.3.2 DMA -- 5.4 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY -- 5.5 FOAM SCREENING: FOAMAT -- REFERENCES -- CHAPTER 6 POLYURETHANE FLEXIBLE FOAMS: CHEMISTRY AND FABRICATION -- 6.1 MAKING POLYURETHANE FOAMS -- 6.1.1 Slabstock Foams -- 6.1.2 Molded Foams -- 6.2 FOAM PROCESSES. 6.2.1 Surfactancy and Catalysis -- 6.3 FLEXIBLE FOAM FORMULATION AND STRUCTURE-PROPERTY RELATIONSHIPS -- 6.3.1 Screening Tests -- 6.3.2 Foam Formulation and Structure-Property Relationships -- REFERENCES -- CHAPTER 7 POLYURETHANE FLEXIBLE FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 7.1 APPLICATIONS -- 7.1.1 Furniture -- 7.1.2 Mattresses and Bedding -- 7.1.3 Transportation -- 7.1.4 The Molded Foam Market -- 7.2 TRENDS IN MOLDED FOAM TECHNOLOGY AND MARKETS -- REFERENCES -- CHAPTER 8 POLYURETHANE RIGID FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 8.1 REGIONAL MARKET DYNAMICS -- 8.2 APPLICATIONS -- 8.2.1 Construction Foams -- 8.2.2 Rigid Construction Foam Market Segments -- 8.2.3 Appliance Foams -- 8.3 BLOWING AGENTS AND INSULATION FUNDAMENTALS -- 8.3.1 Blowing Agents -- 8.3.2 Blowing Agent Phase‐Out Schedule -- 8.4 INSULATION FUNDAMENTALS -- 8.5 TRENDS IN RIGID FOAMS TECHNOLOGY -- REFERENCES -- CHAPTER 9 POLYURETHANE ELASTOMERS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 9.1 REGIONAL MARKET DYNAMICS -- 9.2 APPLICATIONS -- 9.2.1 Footwear -- 9.2.2 Nonfootwear Elastomer Applications and Methods of Manufacture -- 9.3 TRENDS IN POLYURETHANE ELASTOMERS -- REFERENCES -- CHAPTER 10 POLYURETHANE ADHESIVES AND COATINGS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 10.1 ADHESIVES AND COATINGS INDUSTRIES: SIMILARITIES AND DIFFERENCES -- 10.2 ADHESIVES -- 10.2.1 Adhesive Formulations -- 10.3 TRENDS IN POLYURETHANE ADHESIVES -- 10.4 COATINGS -- 10.4.1 Polyurethane Coating Formulations -- 10.4.2 Trends in Polyurethane Coatings -- REFERENCES -- CHAPTER 11 SPECIAL TOPIC: MEDICAL USES OF POLYURETHANE -- 11.1 MARKETS AND PARTICIPANTS -- 11.2 TECHNOLOGY -- 11.2.1 Catheters -- 11.2.2 Wound Dressings -- 11.2.3 Bioabsorbable Polyurethanes -- 11.2.4 Hydrogels -- 11.2.5 Gloves and Condoms -- 11.3 FUTURE TRENDS -- REFERENCES. CHAPTER 12 SPECIAL TOPIC: NONISOCYANATE ROUTES TO POLYURETHANES -- 12.1 GOVERNMENTAL REGULATION OF ISOCYANATES -- 12.2 NONISOCYANATE ROUTES TO POLYURETHANES -- 12.2.1 Reactions of Polycyclic Carbonates with Polyamines -- 12.2.2 Direct Transformations of Amines to Urethanes -- 12.2.3 Reactions of Polycarbamates -- 12.2.4 Conversion of Hydroxamic Acids to Polyurethane -- 12.2.5 Conversion of Hydroxylamines to Polyurethanes -- REFERENCES -- CHAPTER 13 POLYURETHANE HYBRID POLYMERS -- 13.1 INTRODUCTION -- 13.2 POLYURETHANE-ACRYLATE HYBRIDS -- 13.3 URETHANE-EPOXY HYBRIDS -- 13.4 URETHANE-SILICONE HYBRIDS -- 13.4.1 Silicone-Modified Prepolymers -- 13.4.2 Urethane-Silicone Hybrids Produced Using Diblock Compatibilizers -- 13.4.3 Hybrids Employing Covalent and Hydrogen‐Bonded Cross-Links -- 13.4.4 Polyurethane Hybridization with Polyhedral Oligomeric Silsesquixanes -- 13.5 POLYURETHANE-POLYOLEFIN HYBRIDS -- 13.6 HYBRIDIZATION VIA TRANSURETHANIFICATION -- REFERENCES -- CHAPTER 14 RECYCLING OF POLYURETHANES -- 14.1 INTRODUCTION -- 14.2 GLYCOLYSIS, HYDROLYSIS, AMINOLYSIS, AND ACIDOLYSIS -- 14.3 PYROLYSIS -- 14.4 RECYCLE FOR FUEL VALUE -- 14.5 REGRINDING AND INCORPORATION -- REFERENCES -- Index -- EULA. |
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| dewey-full | 668.4/239 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 668 - Technology of other organic products |
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| dewey-search | 668.4/239 |
| dewey-sort | 3668.4 3239 |
| dewey-tens | 660 - Chemical engineering |
| discipline | Chemie / Pharmazie Chemie |
| discipline_str_mv | Chemie / Pharmazie Chemie |
| edition | Second edition |
| format | Electronic eBook |
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and technology</subfield></datafield><datafield tag="500" ind1=" " ind2=" "><subfield code="a">Description based on publisher supplied metadata and other sources</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">Cover -- Title Page -- Copyright Page -- Contents -- PREFACE -- ACKNOWLEDGMENTS -- CHAPTER 1 INTRODUCTION -- REFERENCES -- CHAPTER 2 POLYURETHANE BUILDING BLOCKS -- 2.1 POLYOLS -- 2.1.1 Polyethers -- 2.1.2 Polyester Polyols -- 2.1.3 Other Polyols -- 2.1.4 Filled Polyols -- 2.1.5 Seed Oil-Derived Polyols -- 2.1.6 Prepolymers -- 2.2 ISOCYANATES -- 2.2.1 TDI -- 2.2.2 Diphenylmethane Diisocyanates (MDI) -- 2.2.3 Aliphatic Isocyanates -- 2.3 CHAIN EXTENDERS -- REFERENCES -- CHAPTER 3 INTRODUCTION TO POLYURETHANE CHEMISTRY -- 3.1 INTRODUCTION -- 3.2 MECHANISM AND CATALYSIS OF URETHANE FORMATION -- 3.3 REACTIONS OF ISOCYANATES WITH ACTIVE HYDROGEN COMPOUNDS -- 3.3.1 Urea Formation -- 3.3.2 Allophanate Formation -- 3.3.3 Formation of Biurets -- 3.3.4 Formation of Uretdione (Isocyanate Dimer) -- 3.3.5 Formation of Carbodiimide -- 3.3.6 Formation of Uretonimine -- 3.3.7 Formation of Amides -- REFERENCES -- CHAPTER 4 THEORETICAL CONCEPTS AND TECHNIQUES IN POLYURETHANE SCIENCE -- 4.1 FORMATION OF POLYURETHANE STRUCTURE -- 4.2 PROPERTIES OF POLYURETHANES -- 4.2.1 Models and Calculations for Polymer Modulus -- 4.2.2 Models for Elastomer Stress-Strain Properties -- 4.2.3 The Polyurethane Glass Transition Temperature -- REFERENCES -- CHAPTER 5 ANALYTICAL CHARACTERIZATION OF POLYURETHANES -- 5.1 ANALYSIS OF REAGENTS FOR MAKING POLYURETHANES -- 5.1.1 Analysis of Polyols -- 5.1.2 Analysis of Isocyanates -- 5.2 INSTRUMENTAL ANALYSIS OF POLYURETHANES -- 5.2.1 Microscopy -- 5.2.2 IR Spectrometry -- 5.2.3 X-Ray Analyses -- 5.3 MECHANICAL ANALYSIS -- 5.3.1 Tensile, Tear, and Elongation Testing -- 5.3.2 DMA -- 5.4 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY -- 5.5 FOAM SCREENING: FOAMAT -- REFERENCES -- CHAPTER 6 POLYURETHANE FLEXIBLE FOAMS: CHEMISTRY AND FABRICATION -- 6.1 MAKING POLYURETHANE FOAMS -- 6.1.1 Slabstock Foams -- 6.1.2 Molded Foams -- 6.2 FOAM PROCESSES.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">6.2.1 Surfactancy and Catalysis -- 6.3 FLEXIBLE FOAM FORMULATION AND STRUCTURE-PROPERTY RELATIONSHIPS -- 6.3.1 Screening Tests -- 6.3.2 Foam Formulation and Structure-Property Relationships -- REFERENCES -- CHAPTER 7 POLYURETHANE FLEXIBLE FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 7.1 APPLICATIONS -- 7.1.1 Furniture -- 7.1.2 Mattresses and Bedding -- 7.1.3 Transportation -- 7.1.4 The Molded Foam Market -- 7.2 TRENDS IN MOLDED FOAM TECHNOLOGY AND MARKETS -- REFERENCES -- CHAPTER 8 POLYURETHANE RIGID FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 8.1 REGIONAL MARKET DYNAMICS -- 8.2 APPLICATIONS -- 8.2.1 Construction Foams -- 8.2.2 Rigid Construction Foam Market Segments -- 8.2.3 Appliance Foams -- 8.3 BLOWING AGENTS AND INSULATION FUNDAMENTALS -- 8.3.1 Blowing Agents -- 8.3.2 Blowing Agent Phase‐Out Schedule -- 8.4 INSULATION FUNDAMENTALS -- 8.5 TRENDS IN RIGID FOAMS TECHNOLOGY -- REFERENCES -- CHAPTER 9 POLYURETHANE ELASTOMERS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 9.1 REGIONAL MARKET DYNAMICS -- 9.2 APPLICATIONS -- 9.2.1 Footwear -- 9.2.2 Nonfootwear Elastomer Applications and Methods of Manufacture -- 9.3 TRENDS IN POLYURETHANE ELASTOMERS -- REFERENCES -- CHAPTER 10 POLYURETHANE ADHESIVES AND COATINGS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 10.1 ADHESIVES AND COATINGS INDUSTRIES: SIMILARITIES AND DIFFERENCES -- 10.2 ADHESIVES -- 10.2.1 Adhesive Formulations -- 10.3 TRENDS IN POLYURETHANE ADHESIVES -- 10.4 COATINGS -- 10.4.1 Polyurethane Coating Formulations -- 10.4.2 Trends in Polyurethane Coatings -- REFERENCES -- CHAPTER 11 SPECIAL TOPIC: MEDICAL USES OF POLYURETHANE -- 11.1 MARKETS AND PARTICIPANTS -- 11.2 TECHNOLOGY -- 11.2.1 Catheters -- 11.2.2 Wound Dressings -- 11.2.3 Bioabsorbable Polyurethanes -- 11.2.4 Hydrogels -- 11.2.5 Gloves and Condoms -- 11.3 FUTURE TRENDS -- REFERENCES.</subfield></datafield><datafield tag="505" ind1="8" ind2=" "><subfield code="a">CHAPTER 12 SPECIAL TOPIC: NONISOCYANATE ROUTES TO POLYURETHANES -- 12.1 GOVERNMENTAL REGULATION OF ISOCYANATES -- 12.2 NONISOCYANATE ROUTES TO POLYURETHANES -- 12.2.1 Reactions of Polycyclic Carbonates with Polyamines -- 12.2.2 Direct Transformations of Amines to Urethanes -- 12.2.3 Reactions of Polycarbamates -- 12.2.4 Conversion of Hydroxamic Acids to Polyurethane -- 12.2.5 Conversion of Hydroxylamines to Polyurethanes -- REFERENCES -- CHAPTER 13 POLYURETHANE HYBRID POLYMERS -- 13.1 INTRODUCTION -- 13.2 POLYURETHANE-ACRYLATE HYBRIDS -- 13.3 URETHANE-EPOXY HYBRIDS -- 13.4 URETHANE-SILICONE HYBRIDS -- 13.4.1 Silicone-Modified Prepolymers -- 13.4.2 Urethane-Silicone Hybrids Produced Using Diblock Compatibilizers -- 13.4.3 Hybrids Employing Covalent and Hydrogen‐Bonded Cross-Links -- 13.4.4 Polyurethane Hybridization with Polyhedral Oligomeric Silsesquixanes -- 13.5 POLYURETHANE-POLYOLEFIN HYBRIDS -- 13.6 HYBRIDIZATION VIA TRANSURETHANIFICATION -- REFERENCES -- CHAPTER 14 RECYCLING OF POLYURETHANES -- 14.1 INTRODUCTION -- 14.2 GLYCOLYSIS, HYDROLYSIS, AMINOLYSIS, AND ACIDOLYSIS -- 14.3 PYROLYSIS -- 14.4 RECYCLE FOR FUEL VALUE -- 14.5 REGRINDING AND INCORPORATION -- REFERENCES -- Index -- EULA.</subfield></datafield><datafield tag="776" ind1="0" ind2="8"><subfield code="i">Erscheint auch als</subfield><subfield code="a">Sonnenschein, Mark F.</subfield><subfield code="t">Polyurethanes</subfield><subfield code="d">Newark : John Wiley & Sons, Incorporated,c2021</subfield><subfield code="n">Druck-Ausgabe, Hardcover</subfield><subfield code="z">978-1-119-66941-8</subfield></datafield><datafield tag="912" ind1=" " ind2=" "><subfield code="a">ZDB-30-PQE</subfield></datafield><datafield tag="999" ind1=" " ind2=" "><subfield code="a">oai:aleph.bib-bvb.de:BVB01-032844688</subfield></datafield><datafield tag="966" ind1="e" ind2=" "><subfield code="u">https://ebookcentral.proquest.com/lib/munchentech/detail.action?docID=6424575</subfield><subfield code="l">TUM01</subfield><subfield code="p">ZDB-30-PQE</subfield><subfield code="q">TUM_PDA_PQE_Kauf</subfield><subfield code="x">Aggregator</subfield><subfield code="3">Volltext</subfield></datafield></record></collection> |
| id | DE-604.BV047442536 |
| illustrated | Not Illustrated |
| index_date | 2024-07-03T18:01:24Z |
| indexdate | 2024-07-10T09:12:16Z |
| institution | BVB |
| isbn | 9781119669470 9781119669463 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-032844688 |
| oclc_num | 1227391384 |
| open_access_boolean | |
| owner | DE-91 DE-BY-TUM |
| owner_facet | DE-91 DE-BY-TUM |
| physical | 1 Online-Ressource Illustrationen, Diagramme |
| psigel | ZDB-30-PQE ZDB-30-PQE TUM_PDA_PQE_Kauf |
| publishDate | 2021 |
| publishDateSearch | 2021 |
| publishDateSort | 2021 |
| publisher | Wiley |
| record_format | marc |
| series2 | Wiley Series on polymer engineering and technology |
| spelling | Sonnenschein, Mark F. Verfasser aut Polyurethanes science, technology, markets, and trends Mark F. Sonnenschein Second edition Hoboken, NJ, USA Wiley 2021 © 2021 1 Online-Ressource Illustrationen, Diagramme txt rdacontent c rdamedia cr rdacarrier Wiley Series on polymer engineering and technology Description based on publisher supplied metadata and other sources Cover -- Title Page -- Copyright Page -- Contents -- PREFACE -- ACKNOWLEDGMENTS -- CHAPTER 1 INTRODUCTION -- REFERENCES -- CHAPTER 2 POLYURETHANE BUILDING BLOCKS -- 2.1 POLYOLS -- 2.1.1 Polyethers -- 2.1.2 Polyester Polyols -- 2.1.3 Other Polyols -- 2.1.4 Filled Polyols -- 2.1.5 Seed Oil-Derived Polyols -- 2.1.6 Prepolymers -- 2.2 ISOCYANATES -- 2.2.1 TDI -- 2.2.2 Diphenylmethane Diisocyanates (MDI) -- 2.2.3 Aliphatic Isocyanates -- 2.3 CHAIN EXTENDERS -- REFERENCES -- CHAPTER 3 INTRODUCTION TO POLYURETHANE CHEMISTRY -- 3.1 INTRODUCTION -- 3.2 MECHANISM AND CATALYSIS OF URETHANE FORMATION -- 3.3 REACTIONS OF ISOCYANATES WITH ACTIVE HYDROGEN COMPOUNDS -- 3.3.1 Urea Formation -- 3.3.2 Allophanate Formation -- 3.3.3 Formation of Biurets -- 3.3.4 Formation of Uretdione (Isocyanate Dimer) -- 3.3.5 Formation of Carbodiimide -- 3.3.6 Formation of Uretonimine -- 3.3.7 Formation of Amides -- REFERENCES -- CHAPTER 4 THEORETICAL CONCEPTS AND TECHNIQUES IN POLYURETHANE SCIENCE -- 4.1 FORMATION OF POLYURETHANE STRUCTURE -- 4.2 PROPERTIES OF POLYURETHANES -- 4.2.1 Models and Calculations for Polymer Modulus -- 4.2.2 Models for Elastomer Stress-Strain Properties -- 4.2.3 The Polyurethane Glass Transition Temperature -- REFERENCES -- CHAPTER 5 ANALYTICAL CHARACTERIZATION OF POLYURETHANES -- 5.1 ANALYSIS OF REAGENTS FOR MAKING POLYURETHANES -- 5.1.1 Analysis of Polyols -- 5.1.2 Analysis of Isocyanates -- 5.2 INSTRUMENTAL ANALYSIS OF POLYURETHANES -- 5.2.1 Microscopy -- 5.2.2 IR Spectrometry -- 5.2.3 X-Ray Analyses -- 5.3 MECHANICAL ANALYSIS -- 5.3.1 Tensile, Tear, and Elongation Testing -- 5.3.2 DMA -- 5.4 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY -- 5.5 FOAM SCREENING: FOAMAT -- REFERENCES -- CHAPTER 6 POLYURETHANE FLEXIBLE FOAMS: CHEMISTRY AND FABRICATION -- 6.1 MAKING POLYURETHANE FOAMS -- 6.1.1 Slabstock Foams -- 6.1.2 Molded Foams -- 6.2 FOAM PROCESSES. 6.2.1 Surfactancy and Catalysis -- 6.3 FLEXIBLE FOAM FORMULATION AND STRUCTURE-PROPERTY RELATIONSHIPS -- 6.3.1 Screening Tests -- 6.3.2 Foam Formulation and Structure-Property Relationships -- REFERENCES -- CHAPTER 7 POLYURETHANE FLEXIBLE FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 7.1 APPLICATIONS -- 7.1.1 Furniture -- 7.1.2 Mattresses and Bedding -- 7.1.3 Transportation -- 7.1.4 The Molded Foam Market -- 7.2 TRENDS IN MOLDED FOAM TECHNOLOGY AND MARKETS -- REFERENCES -- CHAPTER 8 POLYURETHANE RIGID FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 8.1 REGIONAL MARKET DYNAMICS -- 8.2 APPLICATIONS -- 8.2.1 Construction Foams -- 8.2.2 Rigid Construction Foam Market Segments -- 8.2.3 Appliance Foams -- 8.3 BLOWING AGENTS AND INSULATION FUNDAMENTALS -- 8.3.1 Blowing Agents -- 8.3.2 Blowing Agent Phase‐Out Schedule -- 8.4 INSULATION FUNDAMENTALS -- 8.5 TRENDS IN RIGID FOAMS TECHNOLOGY -- REFERENCES -- CHAPTER 9 POLYURETHANE ELASTOMERS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 9.1 REGIONAL MARKET DYNAMICS -- 9.2 APPLICATIONS -- 9.2.1 Footwear -- 9.2.2 Nonfootwear Elastomer Applications and Methods of Manufacture -- 9.3 TRENDS IN POLYURETHANE ELASTOMERS -- REFERENCES -- CHAPTER 10 POLYURETHANE ADHESIVES AND COATINGS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 10.1 ADHESIVES AND COATINGS INDUSTRIES: SIMILARITIES AND DIFFERENCES -- 10.2 ADHESIVES -- 10.2.1 Adhesive Formulations -- 10.3 TRENDS IN POLYURETHANE ADHESIVES -- 10.4 COATINGS -- 10.4.1 Polyurethane Coating Formulations -- 10.4.2 Trends in Polyurethane Coatings -- REFERENCES -- CHAPTER 11 SPECIAL TOPIC: MEDICAL USES OF POLYURETHANE -- 11.1 MARKETS AND PARTICIPANTS -- 11.2 TECHNOLOGY -- 11.2.1 Catheters -- 11.2.2 Wound Dressings -- 11.2.3 Bioabsorbable Polyurethanes -- 11.2.4 Hydrogels -- 11.2.5 Gloves and Condoms -- 11.3 FUTURE TRENDS -- REFERENCES. CHAPTER 12 SPECIAL TOPIC: NONISOCYANATE ROUTES TO POLYURETHANES -- 12.1 GOVERNMENTAL REGULATION OF ISOCYANATES -- 12.2 NONISOCYANATE ROUTES TO POLYURETHANES -- 12.2.1 Reactions of Polycyclic Carbonates with Polyamines -- 12.2.2 Direct Transformations of Amines to Urethanes -- 12.2.3 Reactions of Polycarbamates -- 12.2.4 Conversion of Hydroxamic Acids to Polyurethane -- 12.2.5 Conversion of Hydroxylamines to Polyurethanes -- REFERENCES -- CHAPTER 13 POLYURETHANE HYBRID POLYMERS -- 13.1 INTRODUCTION -- 13.2 POLYURETHANE-ACRYLATE HYBRIDS -- 13.3 URETHANE-EPOXY HYBRIDS -- 13.4 URETHANE-SILICONE HYBRIDS -- 13.4.1 Silicone-Modified Prepolymers -- 13.4.2 Urethane-Silicone Hybrids Produced Using Diblock Compatibilizers -- 13.4.3 Hybrids Employing Covalent and Hydrogen‐Bonded Cross-Links -- 13.4.4 Polyurethane Hybridization with Polyhedral Oligomeric Silsesquixanes -- 13.5 POLYURETHANE-POLYOLEFIN HYBRIDS -- 13.6 HYBRIDIZATION VIA TRANSURETHANIFICATION -- REFERENCES -- CHAPTER 14 RECYCLING OF POLYURETHANES -- 14.1 INTRODUCTION -- 14.2 GLYCOLYSIS, HYDROLYSIS, AMINOLYSIS, AND ACIDOLYSIS -- 14.3 PYROLYSIS -- 14.4 RECYCLE FOR FUEL VALUE -- 14.5 REGRINDING AND INCORPORATION -- REFERENCES -- Index -- EULA. Erscheint auch als Sonnenschein, Mark F. Polyurethanes Newark : John Wiley & Sons, Incorporated,c2021 Druck-Ausgabe, Hardcover 978-1-119-66941-8 |
| spellingShingle | Sonnenschein, Mark F. Polyurethanes science, technology, markets, and trends Cover -- Title Page -- Copyright Page -- Contents -- PREFACE -- ACKNOWLEDGMENTS -- CHAPTER 1 INTRODUCTION -- REFERENCES -- CHAPTER 2 POLYURETHANE BUILDING BLOCKS -- 2.1 POLYOLS -- 2.1.1 Polyethers -- 2.1.2 Polyester Polyols -- 2.1.3 Other Polyols -- 2.1.4 Filled Polyols -- 2.1.5 Seed Oil-Derived Polyols -- 2.1.6 Prepolymers -- 2.2 ISOCYANATES -- 2.2.1 TDI -- 2.2.2 Diphenylmethane Diisocyanates (MDI) -- 2.2.3 Aliphatic Isocyanates -- 2.3 CHAIN EXTENDERS -- REFERENCES -- CHAPTER 3 INTRODUCTION TO POLYURETHANE CHEMISTRY -- 3.1 INTRODUCTION -- 3.2 MECHANISM AND CATALYSIS OF URETHANE FORMATION -- 3.3 REACTIONS OF ISOCYANATES WITH ACTIVE HYDROGEN COMPOUNDS -- 3.3.1 Urea Formation -- 3.3.2 Allophanate Formation -- 3.3.3 Formation of Biurets -- 3.3.4 Formation of Uretdione (Isocyanate Dimer) -- 3.3.5 Formation of Carbodiimide -- 3.3.6 Formation of Uretonimine -- 3.3.7 Formation of Amides -- REFERENCES -- CHAPTER 4 THEORETICAL CONCEPTS AND TECHNIQUES IN POLYURETHANE SCIENCE -- 4.1 FORMATION OF POLYURETHANE STRUCTURE -- 4.2 PROPERTIES OF POLYURETHANES -- 4.2.1 Models and Calculations for Polymer Modulus -- 4.2.2 Models for Elastomer Stress-Strain Properties -- 4.2.3 The Polyurethane Glass Transition Temperature -- REFERENCES -- CHAPTER 5 ANALYTICAL CHARACTERIZATION OF POLYURETHANES -- 5.1 ANALYSIS OF REAGENTS FOR MAKING POLYURETHANES -- 5.1.1 Analysis of Polyols -- 5.1.2 Analysis of Isocyanates -- 5.2 INSTRUMENTAL ANALYSIS OF POLYURETHANES -- 5.2.1 Microscopy -- 5.2.2 IR Spectrometry -- 5.2.3 X-Ray Analyses -- 5.3 MECHANICAL ANALYSIS -- 5.3.1 Tensile, Tear, and Elongation Testing -- 5.3.2 DMA -- 5.4 NUCLEAR MAGNETIC RESONANCE SPECTROSCOPY -- 5.5 FOAM SCREENING: FOAMAT -- REFERENCES -- CHAPTER 6 POLYURETHANE FLEXIBLE FOAMS: CHEMISTRY AND FABRICATION -- 6.1 MAKING POLYURETHANE FOAMS -- 6.1.1 Slabstock Foams -- 6.1.2 Molded Foams -- 6.2 FOAM PROCESSES. 6.2.1 Surfactancy and Catalysis -- 6.3 FLEXIBLE FOAM FORMULATION AND STRUCTURE-PROPERTY RELATIONSHIPS -- 6.3.1 Screening Tests -- 6.3.2 Foam Formulation and Structure-Property Relationships -- REFERENCES -- CHAPTER 7 POLYURETHANE FLEXIBLE FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 7.1 APPLICATIONS -- 7.1.1 Furniture -- 7.1.2 Mattresses and Bedding -- 7.1.3 Transportation -- 7.1.4 The Molded Foam Market -- 7.2 TRENDS IN MOLDED FOAM TECHNOLOGY AND MARKETS -- REFERENCES -- CHAPTER 8 POLYURETHANE RIGID FOAMS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 8.1 REGIONAL MARKET DYNAMICS -- 8.2 APPLICATIONS -- 8.2.1 Construction Foams -- 8.2.2 Rigid Construction Foam Market Segments -- 8.2.3 Appliance Foams -- 8.3 BLOWING AGENTS AND INSULATION FUNDAMENTALS -- 8.3.1 Blowing Agents -- 8.3.2 Blowing Agent Phase‐Out Schedule -- 8.4 INSULATION FUNDAMENTALS -- 8.5 TRENDS IN RIGID FOAMS TECHNOLOGY -- REFERENCES -- CHAPTER 9 POLYURETHANE ELASTOMERS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 9.1 REGIONAL MARKET DYNAMICS -- 9.2 APPLICATIONS -- 9.2.1 Footwear -- 9.2.2 Nonfootwear Elastomer Applications and Methods of Manufacture -- 9.3 TRENDS IN POLYURETHANE ELASTOMERS -- REFERENCES -- CHAPTER 10 POLYURETHANE ADHESIVES AND COATINGS: MANUFACTURE, APPLICATIONS, MARKETS, AND TRENDS -- 10.1 ADHESIVES AND COATINGS INDUSTRIES: SIMILARITIES AND DIFFERENCES -- 10.2 ADHESIVES -- 10.2.1 Adhesive Formulations -- 10.3 TRENDS IN POLYURETHANE ADHESIVES -- 10.4 COATINGS -- 10.4.1 Polyurethane Coating Formulations -- 10.4.2 Trends in Polyurethane Coatings -- REFERENCES -- CHAPTER 11 SPECIAL TOPIC: MEDICAL USES OF POLYURETHANE -- 11.1 MARKETS AND PARTICIPANTS -- 11.2 TECHNOLOGY -- 11.2.1 Catheters -- 11.2.2 Wound Dressings -- 11.2.3 Bioabsorbable Polyurethanes -- 11.2.4 Hydrogels -- 11.2.5 Gloves and Condoms -- 11.3 FUTURE TRENDS -- REFERENCES. CHAPTER 12 SPECIAL TOPIC: NONISOCYANATE ROUTES TO POLYURETHANES -- 12.1 GOVERNMENTAL REGULATION OF ISOCYANATES -- 12.2 NONISOCYANATE ROUTES TO POLYURETHANES -- 12.2.1 Reactions of Polycyclic Carbonates with Polyamines -- 12.2.2 Direct Transformations of Amines to Urethanes -- 12.2.3 Reactions of Polycarbamates -- 12.2.4 Conversion of Hydroxamic Acids to Polyurethane -- 12.2.5 Conversion of Hydroxylamines to Polyurethanes -- REFERENCES -- CHAPTER 13 POLYURETHANE HYBRID POLYMERS -- 13.1 INTRODUCTION -- 13.2 POLYURETHANE-ACRYLATE HYBRIDS -- 13.3 URETHANE-EPOXY HYBRIDS -- 13.4 URETHANE-SILICONE HYBRIDS -- 13.4.1 Silicone-Modified Prepolymers -- 13.4.2 Urethane-Silicone Hybrids Produced Using Diblock Compatibilizers -- 13.4.3 Hybrids Employing Covalent and Hydrogen‐Bonded Cross-Links -- 13.4.4 Polyurethane Hybridization with Polyhedral Oligomeric Silsesquixanes -- 13.5 POLYURETHANE-POLYOLEFIN HYBRIDS -- 13.6 HYBRIDIZATION VIA TRANSURETHANIFICATION -- REFERENCES -- CHAPTER 14 RECYCLING OF POLYURETHANES -- 14.1 INTRODUCTION -- 14.2 GLYCOLYSIS, HYDROLYSIS, AMINOLYSIS, AND ACIDOLYSIS -- 14.3 PYROLYSIS -- 14.4 RECYCLE FOR FUEL VALUE -- 14.5 REGRINDING AND INCORPORATION -- REFERENCES -- Index -- EULA. |
| title | Polyurethanes science, technology, markets, and trends |
| title_auth | Polyurethanes science, technology, markets, and trends |
| title_exact_search | Polyurethanes science, technology, markets, and trends |
| title_exact_search_txtP | Polyurethanes science, technology, markets, and trends |
| title_full | Polyurethanes science, technology, markets, and trends Mark F. Sonnenschein |
| title_fullStr | Polyurethanes science, technology, markets, and trends Mark F. Sonnenschein |
| title_full_unstemmed | Polyurethanes science, technology, markets, and trends Mark F. Sonnenschein |
| title_short | Polyurethanes |
| title_sort | polyurethanes science technology markets and trends |
| title_sub | science, technology, markets, and trends |
| work_keys_str_mv | AT sonnenscheinmarkf polyurethanessciencetechnologymarketsandtrends |